KR102298724B1 - Ice maker and method for controlling the same - Google Patents

Abstract

An ice maker and a method for controlling the same are disclosed. An ice maker according to an embodiment of the present invention includes an ice-making space accommodating ice-making water therein, the ice-making space is partitioned through a plurality of partition walls, an ice tray fixed in the ice-making chamber, and an upper portion of the ice tray, , an ejector rotating in a predetermined direction to icy the ice in the ice tray, and a first heat exchanger provided in contact with an outer surface of the ice tray, wherein the first heat exchanger cools the ice tray in the ice making step and removes the ice Step to heat the ice tray.

Description

Ice maker and method for controlling the same

An embodiment of the present invention relates to an ice maker, and more particularly, to an ice maker having an ejector and a control method therefor.

BACKGROUND ART In general, a refrigerator includes a refrigerating chamber in which food is refrigerated and a freezing chamber in which food is frozen. In this case, an ice maker for producing ice is installed in the freezing compartment or the refrigerating compartment. Conventionally, when ice making is completed, an ice heater formed on the outer peripheral surface of the ice tray is operated to separate the ice in the ice tray from the inner wall of the ice tray, and then the ice is transferred. The ice heater is generally a U-shaped sheath heater (Sheath Heater) is used. In this case, a lot of power is consumed to heat the ice tray through the ice heater. In addition, it takes time for the ice heater to rise to a predetermined temperature, and it takes a certain amount of time to separate the ice from the inner wall of the ice tray through the ice heater. As a result, power consumption increases and there is a problem in that the temperature in the ice making chamber rises.

Korea Patent Publication No. 2012-0030686 (2012.03.29)

An embodiment of the present invention is to provide an ice maker capable of reducing power consumption and a method for controlling the same.

An ice maker according to an embodiment of the present invention includes: an ice tray having an ice making space accommodating ice making water therein, the ice making space being partitioned through a plurality of partition walls, and fixed in the ice making chamber; an ejector provided on the ice tray and rotating in a predetermined direction to eject the ice in the ice tray; and a first heat exchanger provided in contact with an outer surface of the ice tray, wherein the first heat exchanger cools the ice tray in the ice making step and heats the ice tray in the ice making step.

The ice maker may include: a first refrigerant circulation line comprising a compression unit for compressing the refrigerant and a second heat exchange unit for heat exchanging the refrigerant discharged from the compression unit, the first refrigerant circulation line constituting a cooling cycle of the refrigerant; a second refrigerant circulation line branched from the discharge end of the compression unit or the second heat exchange unit and connected to the first heat exchange unit to heat the ice tray; and a first refrigerant switching valve provided at the branching point of the second refrigerant circulation line and controlling a flow direction of the refrigerant according to the ice making step and the ice breaking step.

The first refrigerant switching valve may open the first refrigerant circulation line and cut off the second refrigerant circulation line in the ice-making step, and cut off the first refrigerant circulation line in the ice-making step and close the second refrigerant circulation line can be opened.

The ice maker may further include a second refrigerant switching valve provided on the inlet side of the first heat exchanger and controlling a flow direction of the refrigerant according to the ice making and ice removal steps.

The second refrigerant switching valve may open the first refrigerant circulation line and cut off the second refrigerant circulation line in the ice-making step, and close the first refrigerant circulation line in the ice-making step and close the second refrigerant circulation line can be opened.

The ejector is activated when a preset time elapses after the first heat exchanger heats the ice tray, or when the temperature of the ice tray becomes higher than or equal to a preset temperature, or when the first heat exchanger heats the ice tray. When the temperature of the ice tray becomes greater than or equal to the preset temperature at a later preset time, the ice tray may be rotated to icy the ice in the ice tray.

The ice maker may be provided in the refrigerator, and may heat the ice tray by introducing a refrigerant discharged from a compression unit or a second heat exchange unit constituting a cooling cycle of the refrigerator into the first heat exchange unit.

The ice maker may heat the ice tray by introducing the refrigerant into the first heat exchanger during a rest mode section of the compression unit.

The ice maker may be provided in the refrigerator and may adjust the ice making cycle according to the operation mode of the compression unit constituting the cooling cycle of the refrigerator.

The ice maker may adjust the completion time of the ice making step or the start time of the ice removing step as the idle mode section of the compression unit.

The ice maker may further include an ice heater provided in contact with an outer surface of the ice tray.

The ice heater may be driven when the ejector does not reach a preset position at a preset time after the ejector starts to rotate.

In a method for controlling an ice machine according to an embodiment of the present invention, an ice tray having an ice-making space accommodating ice-making water is provided therein, the ice-making space is partitioned through a plurality of partition walls, the ice tray being fixed in the ice-making chamber, and the ice tray A method of controlling an ice maker, the method comprising: an ejector provided on an upper portion of an ice tray and rotating in a preset direction to remove ice from the ice tray, the method comprising: supplying ice-making water into the ice tray; cooling the ice tray through a first heat exchanger in contact with an outer surface of the ice tray; checking whether the ice making water has completed ice making; and heating the ice tray through the first heat exchange unit when the ice-making water is completely ice-making.

The cooling of the ice tray may include opening a first refrigerant circulation line constituting a cooling cycle through a refrigerant switching valve and blocking a second refrigerant circulation line heating the ice tray.

In the heating of the ice tray, a first refrigerant circulation line constituting a cooling cycle may be blocked through a refrigerant switching valve, and a second refrigerant circulation line configured to heat the ice tray may be opened.

After the heating of the ice tray, when a preset time elapses, when the temperature of the ice tray becomes higher than or equal to a preset temperature, or when the temperature of the ice tray becomes higher than or equal to a preset temperature at a preset time The method may further include rotating the ejector to move the ice in the ice tray.

After the heating of the ice tray, the method may further include driving an ice heater provided in contact with an outer surface of the ice tray after a preset waiting time has elapsed.

The heating of the ice tray may include driving an ice heater provided in contact with an outer surface of the ice tray to heat the ice tray together with the first heat exchanger for a preset time.

after heating the ice tray, rotating the ejector after a preset time has elapsed; and reheating the ice tray through the first heat exchanger when the ejector does not reach a preset position at a preset time.

The ice maker is provided in the refrigerator, and the heating of the ice tray may include introducing a refrigerant discharged from a compression unit or a second heat exchange unit constituting a cooling cycle of the refrigerator into the first heat exchange unit to the ice tray. can be heated.

The heating of the ice tray may include heating the ice tray by introducing the refrigerant into the first heat exchanger during a rest mode section of the compression unit.

According to an embodiment of the present invention, the ice in the ice tray is moved without a separate ice heater by cooling the ice tray in the ice making step and heating the ice tray in the ice making step through the first heat exchanger provided on the lower surface of the ice tray. be able to do Accordingly, it is possible to reduce the manufacturing cost of the ice maker and to reduce power consumption for separating ice from the inner wall of the ice tray. And, since the high-temperature refrigerant flows directly into the first heat exchanger, the time required to separate the ice from the inner wall of the ice tray can be reduced. Thereby, it is possible to minimize the temperature rise in the ice making chamber while the ice is separated from the inner wall of the ice tray. In addition, in the case of an ice maker having an ice heater, the ice heater is operated auxiliary only when the first heat exchanger fails to perform its role, thereby reducing power consumption due to the ice heater.

1 is a view schematically showing an ice maker according to an embodiment of the present invention;
2 is a view schematically showing a circulation path of a refrigerant in an ice maker according to an embodiment of the present invention;
3 is a flowchart illustrating a method for controlling an ice maker according to an embodiment of the present invention;
4 is a view showing an operation mode of the compression unit according to the internal temperature of the refrigerator in the ice maker according to the embodiment of the present invention;

Hereinafter, specific embodiments of an ice maker and a control method thereof of the present invention will be described with reference to FIGS. 1 to 4 . However, this is only an exemplary embodiment and the present invention is not limited thereto.

In the description of the present invention, if it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the content throughout this specification.

The technical spirit of the present invention is determined by the claims, and the following examples are only one means for efficiently explaining the technical spirit of the present invention to those of ordinary skill in the art to which the present invention belongs.

1 is a view schematically showing an ice maker according to an embodiment of the present invention.

Referring to FIG. 1 , the ice maker 100 may include an ice tray 102 , an ejector 104 , a first heat exchange unit 106 , and a water supply unit 108 . Here, the ejector 104 is connected to a motor (not shown) and is formed to be spaced apart from each other on the ejector shaft 104-1 and the ejector shaft 104-1 rotating by the driving force of the motor (not shown). It may include a pin 104 - 2 . In this case, the motor (not shown) may be provided in a control box (not shown) provided on one side of the ice tray 102 . The ice maker 100 may be provided in the ice maker of the refrigerator.

The ice tray 102 has an ice-making space for accommodating ice-making water therein. The inside of the ice tray 102 may be formed in a semi-circular arc shape. A plurality of partition walls (not shown) may be formed inside the ice tray 102 to separate the ice-making space into a plurality of spaces. Each of the separated ice-making spaces in the ice tray 102 may be formed to correspond to the ejector pins 104 - 2 . For example, the ice tray 102 may be fixedly provided in the ice making chamber of the refrigerator. The ice making chamber of the refrigerator may be provided in the refrigerating chamber of the refrigerator or may be provided in the freezing chamber of the refrigerator.

The ejector 104 may be formed on the ice tray 102 . The ejector 104 serves to remove the ice in the ice tray 102 when the ice-making water in the ice tray 102 is completed. For example, the ejector 104 may take out the ice in the ice tray 102 while rotating in the clockwise direction in FIG. 1 to make the ice. When the ejector pin 104-2 is provided to correspond to each ice-making space in the ice tray 102, the ejector pin 104-2 rotates clockwise to remove the ice formed in each ice-making space in the ice tray 102. It is taken out of the tray 102 and iced. The ice removed by the ejector 104 is stored in an ice bank (not shown) provided under the ice tray 102 .

The ejector 104 may be rotated after a preset time has elapsed from a point in time when the first heat exchanger 106 heats the ice tray 102 in the ice-moving step to ice the ice in the ice tray 102 . The ejector 104 rotates when the temperature of the ice tray 102 becomes higher than a preset temperature after the first heat exchanger 106 heats the ice tray 102 to remove the ice in the ice tray 102 . may be

The first heat exchanger 106 may be provided under the ice tray 102 . The first heat exchanger 106 may be in close contact with the outer surface of the ice tray 102 under the ice tray 102 . The first heat exchanger 106 may be provided by insert-molding the ice tray 102 . In this case, the first heat exchanger 106 may be in close contact with the ice tray 102 . That is, there is no gap between the first heat exchanger 106 and the ice tray 102 so that they can be in close contact with each other. The first heat exchanger 106 may be provided in a U-shape under the ice tray 102 , but the shape of the first heat exchanger 106 is not limited thereto. For example, the first heat exchanger 106 may be formed of a refrigerant pipe through which the refrigerant may move. The first heat exchanger 106 serves to cool the ice tray 102 by supplying cold air to the ice tray 102 in the ice making step. In addition, the first heat exchanger 106 serves to heat the ice tray 102 by supplying heat to the ice tray 102 in the ice moving step. Here, the ice making step refers to a step of freezing the ice making water in the ice tray 102 after the ice making water is supplied to the inside of the ice tray 102 . The ice-removing step refers to a step in which the ice-making water in the ice tray 102 is completed to ice the ice in the ice tray 102 . The first heat exchanger 106 serves to separate the ice in the ice tray 102 from the inner wall of the ice tray 102 by heating the ice tray 102 in the ice-moving step. That is, the first heat exchanger 106 heats the ice tray 102 instead of an ice heater (not shown) when the ice making step is completed and the ice moving step is started.

In the embodiment of the present invention, the first heat exchanger 106 cools the ice tray 102 in the ice-making step, and heats the ice tray 102 in the ice-making step to separate ice from the inner wall of the ice tray 102 . By doing so, the ice in the ice tray 102 can be iced without a separate icing heater. Accordingly, it is possible to reduce the manufacturing cost of the ice maker 100 and reduce power consumption for driving the ice heater. Here, the first heat exchanger 106 may constitute a part of the cooling cycle of the ice maker 100 . A detailed description thereof will be described later with reference to FIG. 2 .

The water supply unit 108 supplies ice-making water to the inside of the ice tray 102 . The water supply unit 108 may supply ice-making water into the ice tray 102 when the ice in the ice tray 102 is completely removed and a new ice-making cycle starts. The ice making cycle may be cycled in the order of the ice making water supply step → ice making step → ice breaking step.

Meanwhile, the ice maker 100 may further include an ice heater (not shown). An ice heater (not shown) may be provided under the ice tray 102 . The ice heater (not shown) may be in close contact with the outer surface of the ice tray 102 at the lower portion of the ice tray 102 . The ice heater (not shown) may be provided in a U-shape at the lower portion of the ice tray 102 , but the shape of the ice heater (not shown) is not limited thereto. The ice heater (not shown) may be provided inside the first heat exchanger 106 under the ice tray 102 , but is not limited thereto and may be provided outside the first heat exchanger 106 . have. Unlike a general ice heater, the ice heater (not shown) does not operate when ice making is completed and ice starts moving. The ice heater (not shown) may operate when a preset ice-incomplete condition is satisfied after the start of the ice-diving.

That is, the general ice heater operates when ice-making is completed and ice-diving is started to separate the ice in the ice tray 102 from the inner wall of the ice tray 102 . However, the ice-diving heater (not shown) according to the embodiment of the present invention does not operate when ice-making is completed and ice-dividing is started. This is because the first heat exchanger 106 serves to separate the ice in the ice tray 102 from the inner wall of the ice tray 102 instead of the ice heater (not shown) after the completion of ice making. In other words, the conventional ice-moving operation starts with the driving of the ice heater after ice-making is completed, but in the embodiment of the present invention, the ice-moving operation is performed after the ice-making is completed (without driving the ice heater (not shown)) of the first heat exchanger 106 may begin with heating the ice tray 102 .

The ice heater (not shown) may operate when the ice in the ice tray 102 is not separated from the inner wall of the ice tray 102 by the first heat exchanger 106 , so that the ice transfer is not completed. That is, the ice heater (not shown) may operate auxiliary to separate the ice in the ice tray 102 from the inner wall of the ice tray 102 when the first heat exchanger 106 does not perform its function. In this way, since the ice heater (not shown) operates as an auxiliary only in preset special conditions, it is possible to reduce the use of the ice heater (not shown), thereby reducing power consumption due to the ice heater (not shown). do.

On the other hand, the ice heater (not shown) operates after the first heat exchanger 106 heats the ice tray 102 and before the ejector 106 rotates (or together with the rotation operation of the ejector 106 ). The ice tray 102 may be heated. That is, the ice heater (not shown) may separate the ice in the ice tray 102 from the inner wall of the ice tray 102 by heating the ice tray 102 together with the first heat exchanger 106 . In this case, since the ice heater (not shown) operates independently to separate the ice in the ice tray 102 even if the operation time is shorter (or the heating temperature is low) than when heating the ice tray 102 , power consumption is consumed. can be reduced

2 is a diagram schematically illustrating a circulation path of a refrigerant in an ice maker according to an embodiment of the present invention.

Referring to FIG. 2 , the cooling cycle of the ice maker 100 may include a first heat exchanger 106 , a compression unit 112 , a second heat exchanger 114 , and an expansion valve 116 . In the cooling cycle of the ice maker 100 , the refrigerant is circulated in the order of the compression unit 112 → the second heat exchange unit 114 → the expansion valve 116 → the first heat exchange unit 106 → the compression unit 112 . can The compression unit 112 , the second heat exchange unit 114 , the expansion valve 116 , and the first heat exchange unit 106 may be interconnected by a refrigerant transfer means or the like. The compression unit 112 , the second heat exchange unit 114 , and the expansion valve 116 not only constitute a cooling cycle of the ice maker 100 , but also cool the refrigerating and freezing compartments of the refrigerator in which the ice maker 100 is mounted. It is also possible to configure the cooling cycle to supply.

Here, the compression unit 112 compresses and discharges the refrigerant heat exchanged in the first heat exchange unit 106 into a high-temperature and high-pressure gas. The second heat exchange unit 114 heat-exchanges the high-temperature and high-pressure refrigerant discharged from the compression unit 112 to condense it into a medium-temperature and high-pressure refrigerant. The expansion valve 116 depressurizes the medium temperature and high pressure refrigerant heat exchanged in the second heat exchange unit 114 . That is, the expansion valve 116 depressurizes the medium-temperature and high-pressure refrigerant to the low-temperature and low-pressure refrigerant. The first heat exchanger 106 heats and evaporates the low-temperature, low-pressure liquid refrigerant decompressed by the expansion valve 116 . Specifically, the refrigerant (low-temperature and low-pressure liquid refrigerant) flowing into one side of the first heat exchange unit 106 is heat exchanged with the ice tray 102 while passing through the first heat exchange unit 106 to thereby perform heat exchange with the ice tray 102 . is cooled and discharged to the other side of the first heat exchange unit 106 . That is, as the low-temperature and low-pressure liquid refrigerant passes through the first heat exchanger 106 , it absorbs heat from the ice tray 102 to cool the ice tray 102 . At this time, the low-temperature and low-pressure liquid refrigerant introduced to one side of the first heat exchange unit 106 evaporates while absorbing heat from the ice tray 102 to become a low-temperature and low-pressure gaseous state. Then, the low-temperature and low-pressure gas refrigerant is discharged to the other side of the first heat exchange unit 106 and flows into the compression unit 112 , and the cooling cycle is circulated.

Here, an evaporator (not shown) may be provided between the expansion valve 116 and the first heat exchanger 106 . In this case, the evaporator (not shown) evaporates the refrigerant decompressed by the expansion valve 116 , and the low-temperature and low-pressure liquid refrigerant that has passed through the evaporator (not shown) may flow into the first heat exchanger 106 . In addition, an evaporator (not shown) may be provided between the first heat exchange unit 106 and the compression unit 112 . In addition, an evaporator (not shown) may be provided between the expansion valve 116 and the first heat exchange unit 106 and between the first heat exchange unit 106 and the compression unit 112 , respectively.

In this way, the first refrigerant is circulated in the order of the compression unit 112 → the second heat exchange unit 114 → the expansion valve 116 → the first heat exchange unit 106 → the compression unit 112 . It is called a circulation line 121 . The first refrigerant circulation line 121 is for cooling the ice tray 102 in the ice making step of the ice maker 100 . The refrigerant in the first refrigerant circulation line 121 passes through the first heat exchange unit 106 to absorb heat from the ice tray 102 to cool the ice tray 102 .

Meanwhile, in the embodiment of the present invention, a second refrigerant circulation line 123 distinguished from the first refrigerant circulation line 121 may be further provided. The second refrigerant circulation line 123 is to separate the ice in the ice tray 102 from the inner wall of the ice tray 102 by heating the ice tray 102 in the ice moving step of the ice maker 100 . The second refrigerant circulation line 123 may be circulated in the order of the compression unit 112 → the first heat exchange unit 106 → the compression unit 112 in the ice moving step of the ice maker 100 .

Specifically, the second refrigerant circulation line 123 is branched from the discharge end of the compression unit 112 to the inlet side of the first heat exchange unit 106 (ie, one side of the first heat exchange unit 106 ). can be connected The second refrigerant circulation line 123 may be branched from the first refrigerant circulation line 121 at the discharge end of the compression unit 112 . Of the second refrigerant circulation line 123 , the path flowing into the compression unit 112 from the outlet side of the first heat exchange unit 106 (ie, the other side of the first heat exchange unit 106 ) is the first refrigerant circulation. It can be shared with line 123 . However, the present invention is not limited thereto and flows into the compression unit 112 from the outlet side of the first heat exchange unit 106 of the second refrigerant circulation line 123 (ie, the other side of the first heat exchange unit 106 ). The path may be provided separately from the first refrigerant circulation line 123 . Here, the high-temperature and high-pressure refrigerant gas is discharged from the discharge end of the compression unit 112 . When the high-temperature and high-pressure refrigerant gas flows into one side of the first heat exchange unit 106 through the second refrigerant circulation line 123 in the ice moving step of the ice maker 100, the high-temperature and high-pressure refrigerant gas is transferred to the first heat exchange unit ( After heating the ice tray 102 while passing through the 106 , it is discharged to the other side of the first heat exchange unit 106 . Since the refrigerant gas discharged from the compression unit 112 is already in a high temperature state, the time required to separate the ice from the inner wall of the ice tray 102 can be reduced. Accordingly, it is possible to minimize the temperature rise in the ice making chamber while the ice is separated from the inner wall of the ice tray 102 . And, since the power consumed to drive the compression unit 112 is less than the power consumed to drive the icing heater, it is possible to reduce power consumption. Here, although it has been described that the second refrigerant circulation line 123 is branched from the discharge end of the compression unit 112 , the present invention is not limited thereto and the second refrigerant circulation line 123 is discharged from the second heat exchange unit 114 . It may be branched from the end and connected to the inlet side of the first heat exchanger 106 . In this case, the second refrigerant circulation line 123 is circulated in the order of the compression unit 112 → the second heat exchange unit 114 → the first heat exchange unit 106 → the compression unit 112 .

A first refrigerant switching valve 125 may be provided at the discharge end of the compression unit 112 to which the second refrigerant circulation line 123 is branched. The first refrigerant switching valve 125 may control the flow direction of the refrigerant according to the ice making stage and the ice breaking stage of the ice maker 100 . For example, in the ice making step of the ice maker 100 , the first refrigerant switching valve 125 may open the first refrigerant circulation line 121 and block the second refrigerant circulation line 123 . In this case, the high-temperature and high-pressure refrigerant gas discharged from the compression unit 112 moves along the first refrigerant circulation line 121 and flows into the second heat exchange unit 114 , and the second refrigerant circulation line 123 is closed. Accordingly, the inflow to one side of the first heat exchange unit 106 is blocked. That is, in the case of the ice making step of the ice maker 100 , the refrigerant discharged from the compression unit 112 through the first refrigerant switching valve 125 circulates along the first refrigerant circulation line 121 (ie, the cooling cycle). By doing so, the first heat exchanger 106 can cool the ice tray 102 to freeze the ice-making water in the ice tray 102 .

In the case of the ice moving step of the ice maker 100 , the first refrigerant switching valve 125 may block the first refrigerant circulation line 121 and open the second refrigerant circulation line 123 . In this case, the high-temperature and high-pressure refrigerant gas discharged from the compression unit 112 moves along the second refrigerant circulation line 123 and flows into one side of the first heat exchange unit 106 , and the first refrigerant circulation line 121 ) along the flow into the second heat exchanger 114 is blocked. That is, in the case of the ice moving step of the ice maker 100 , the refrigerant discharged from the compression unit 112 through the first refrigerant switching valve 125 circulates along the second refrigerant circulation line 123 , so that the first heat exchange The unit 106 may heat the ice tray 102 to separate the ice in the ice tray 102 from the inner wall of the ice tray 102 .

The ice maker 100 may include a temperature sensor (not shown) that measures the temperature of the ice tray 102 . When the temperature of the ice tray 102 is equal to or less than the first preset temperature, the temperature sensor (not shown) may determine that the ice making step is complete and generate an ice making completion signal to the first refrigerant switching valve 125 . When an ice-making completion signal is generated from a temperature sensor (not shown), the first refrigerant switching valve 125 blocks the first refrigerant circulation line 121 for a preset time and the second refrigerant circulation line 123 is open. can In addition, the temperature sensor (not shown) generates a heating stop signal when the temperature of the ice tray 102 becomes greater than or equal to a preset second temperature after the first heat exchanger 106 heats the ice tray 102 . 1 It can be generated by the refrigerant switching valve 125 . The first refrigerant switching valve 125 blocks the first refrigerant circulation line 121 and the second refrigerant circulation line 123 is opened after an ice-making completion signal is generated from the temperature sensor (not shown) until a heating stop signal is generated. can do.

Meanwhile, a second refrigerant switching valve 127 may be further provided at the inlet side of the first heat exchange unit 106 . The second refrigerant switching valve 127 may control the flow direction of the refrigerant according to the ice making stage and the ice breaking stage of the ice maker 100 . For example, in the ice making step of the ice maker 100 , the second refrigerant switching valve 127 may open the first refrigerant circulation line 121 and block the second refrigerant circulation line 123 . That is, in the case of the ice making step of the ice maker 100 , the second refrigerant switching valve 127 opens the first refrigerant circulation line 121 so that the low-temperature and low-pressure liquid refrigerant decompressed by the expansion valve 116 is exchanged for the first heat. It may be introduced into one side of the part 106 . In addition, the second refrigerant switching valve 127 blocks the second refrigerant circulation line 123 so that the high-temperature and high-pressure refrigerant remaining in the second refrigerant circulation line 123 flows into one side of the first heat exchange unit 106 . can be prevented from becoming

In the case of the ice moving step of the ice maker 100 , the second refrigerant switching valve 127 may open the second refrigerant circulation line 123 and block the first refrigerant circulation line 121 . That is, in the ice moving stage of the ice maker 100 , the second refrigerant switching valve 127 opens the second refrigerant circulation line 123 so that the high-temperature and high-pressure refrigerant gas discharged from the compression unit 112 is exchanged for the first heat. It may be introduced into one side of the part 106 . In addition, the second refrigerant switching valve 127 blocks the first refrigerant circulation line 121 so that the low-temperature and low-pressure refrigerant remaining in the first refrigerant circulation line 121 flows into one side of the first heat exchange unit 106 . can be prevented from becoming In addition, when the second refrigerant switching valve 127 blocks the first refrigerant circulation line 121 , the high temperature and high pressure flowing into one side of the first heat exchange unit 106 along the second refrigerant circulation line 123 . It is possible to prevent the refrigerant gas from flowing into the first refrigerant circulation line 121 . As the first refrigerant switching valve 125 and the second refrigerant switching valve 127 , for example, a three-way valve may be used.

3 is a flowchart illustrating a method for controlling an ice maker according to an embodiment of the present invention.

Referring to FIG. 3 , when the ice in the ice tray 102 is completely moved, the water supply unit 108 may supply ice-making water to the inside of the ice tray 102 ( S101 ). When the ice in the ice tray 102 is finished moving, when the ice bank (not shown) is full of ice (that is, when full ice is detected), the water supply unit 108 is discharged to the inside of the ice tray 102 . Ice water supply can be stopped. The ice maker 100 may be provided with an ice full detection unit (not shown) that detects whether the ice bank (not shown) is full of ice.

Next, the ice through the cooling cycle of the ice maker 100 (compression unit 112 → second heat exchange unit 114 → expansion valve 116 → first heat exchange unit 106 → compression unit 112) The tray 102 is cooled (S103). At this time, the low-temperature and low-pressure liquid refrigerant passes through the first heat exchanger 106 and absorbs heat from the ice tray 102 to cool the ice tray 102 . Here, the first refrigerant switching valve 125 and the second refrigerant switching valve 127 may open the first refrigerant circulation line 121 and block the second refrigerant circulation line 123 , respectively.

Next, the ice maker 100 determines whether ice making is complete ( S105 ). That is, the ice maker 100 determines whether the ice making water in the ice tray 102 has completed ice making. In this case, the ice maker 100 may determine whether the ice making is complete through a temperature sensor (not shown). For example, when the temperature of the ice tray 102 measured through a temperature sensor (not shown) is below a preset first temperature, the ice maker 100 determines that the ice-making water in the ice tray 102 is complete. can However, the present invention is not limited thereto, and the ice maker 100 may determine whether the ice making is complete in various known methods.

As a result of determination in step S105 , when ice making is completed, the ice maker 100 heats the ice tray 102 through the first heat exchanger 106 ( S107 ). The ice maker 100 may heat the ice tray 102 by introducing a high-temperature and high-pressure refrigerant gas (or medium-temperature and high-pressure refrigerant liquid) into the first heat exchanger 106 through the second refrigerant circulation line 123 . . Here, the first refrigerant switching valve 125 and the second refrigerant switching valve 127 may block the first refrigerant circulation line 121 and open the second refrigerant circulation line 123 , respectively.

Next, the ice maker 100 checks whether a preset time has elapsed ( S109 ). As a result of checking in step S 109 , when the preset time has elapsed, the ice maker 100 rotates the ejector 104 in a preset direction ( S 111 ). That is, the ice maker 100 heats the ice tray 102 through the first heat exchanger 106 for a preset time, and then moves the ejector 104 in a preset direction (that is, ice in the ice tray 102 ). direction) can be rotated.

Next, the ice maker 100 checks whether the ice removal by the ejector 104 has been completed ( S113 ). When the ice in the ice tray 102 is separated from the inner wall of the ice tray 102 by the first heat exchanger 106 heating the ice tray 102 for a preset time, the ejector 104 rotates Ice in the tray 102 is taken out to complete the ice transfer. On the other hand, if the ice in the ice tray 102 is not separated from the inner wall of the ice tray 102 even after the first heat exchanger 106 has heated the ice tray 102 for a preset time, the ejector 104 is rotated. However, the ice in the ice tray 102 does not move. Here, after rotating the ejector 104 , the ice maker 100 may check whether the ice transfer is complete through whether the ejector pin 104 - 2 reaches a preset position within a preset time. For example, the ejector 104 may complete the divergence by one rotation clockwise from the home position. The ice maker 100 determines that the ice removal by the ejector 104 is completed when the ejector 104 starts to rotate clockwise from the home position and then reaches the home position (ie, the preset position) again within a preset time. can do. When the ice maker 100 does not reach the home position (ie, the preset position) again within a preset time after the ejector 104 starts to rotate clockwise from the home position, the ice removal by the ejector 104 is not completed. It can be concluded that it is not The ice maker 100 may include a position detecting unit (not shown) for detecting the rotational position of the ejector 104 . However, the present invention is not limited thereto, and whether the migration is completed by the ejector 104 may be determined by other methods.

As a result of checking in step S113 , when the ice removal by the ejector 104 is not completed, the ice maker 100 reheats the ice tray 102 through the first heat exchanger 106 ( S115 ). That is, when the ice in the ice tray 102 is not separated from the inner wall of the ice tray 102 even after the ice tray 102 is heated through the first heat exchange unit 106 for a preset time, the first heat exchanger unit The ice in the ice tray 102 may be separated from the inner wall of the ice tray 102 by reheating the ice tray 102 through the 106 .

Meanwhile, although it has been described herein that the first heat exchanger 106 heats the ice tray 102 for a preset time, the present invention is not limited thereto. The ice tray 102 may be heated until it reaches a preset second temperature or higher. The ejector 104 rotates when a preset time elapses after the first heat exchanger 106 heats the ice tray 102 or when the temperature of the ice tray 102 becomes greater than or equal to the second preset temperature. In addition, the ejector 104 may rotate when the temperature of the ice tray 102 becomes greater than or equal to the second preset temperature at a preset time after the first heat exchanger 106 heats the ice tray 102 . . The ice maker 100 may include a controller (not shown) that controls the overall operation of the ice maker 100 . A control unit (not shown) may be provided in a control box provided on one side of the ice tray 102 .

In addition, here, it has been described that the ice tray 102 is reheated through the first heat exchange unit 106 when the evacuation is not completed as a result of the confirmation in step S113 , but the present invention is not limited thereto. For example, when an ice heater (not shown) is provided in the ice maker 100 , the ice tray 102 may be heated by driving the ice heater (not shown). In this case, the ice heater (not shown) is not driven at the start stage of the ice moving step, but is driven after a predetermined waiting time has elapsed. The ice heater (not shown) may be driven after a preset waiting time has elapsed after the start of the ice step. As such, when the first heat exchanger 106 primarily heats the ice tray 102 and the ice in the ice tray 102 is not separated from the inner wall of the ice tray 102 by the primary heating, the ice A heater (not shown) may secondarily heat the ice tray 102, but is not limited thereto, and the first heat exchanger 106 and an ice heater (not shown) may heat the ice tray 102 together. have.

Meanwhile, the injection timing of the hot gas into the first heat exchange unit 106 through the second refrigerant circulation line 123 may be linked with the operation mode of the compression unit 112 . Here, the hot gas refers to a refrigerant injected (or introduced) into the first heat exchanger 106 through the second refrigerant circulation line 123 for heating the ice tray 102 . This will be described with reference to FIG. 4 . 4 is a diagram illustrating an operation mode of the compression unit according to the internal temperature of the refrigerator in the ice maker according to the embodiment of the present invention.

Referring to FIG. 4 , the compression unit 112 may change the operation mode according to the internal temperature of the refrigerator. Here, the freezer temperature may be the freezer temperature of the ice making chamber of the refrigerator in which the ice maker 100 is mounted. However, the present invention is not limited thereto, and the refrigerator temperature may be the refrigerator compartment temperature of the refrigerator in which the ice maker 100 is mounted. For example, when the internal temperature of the refrigerator falls to the preset first temperature T1 , the compression unit 112 may be operated in the idle mode. Here, the idle mode may include a case in which the operation of the compression unit 112 is stopped or the compression unit 112 is operated at a lower speed than the normal driving mode (or operated at a low output). When the compression unit 112 is operated in the idle mode, the internal temperature of the refrigerator starts to rise from the preset first temperature T1 . When the internal temperature of the refrigerator rises to the preset second temperature T2 , the compression unit 112 may be operated in a normal driving mode. The normal driving mode is a mode operated to cool the internal temperature of the refrigerator to a preset first temperature T1. That is, the normal driving mode is a mode in which the internal temperature of the refrigerator is cooled to the preset first temperature T1 through the first refrigerant circulation line 121 in the cooling cycle. When the internal temperature of the refrigerator falls to the preset first temperature T1 , the compression unit 112 may be operated again in the idle mode. As such, the compression unit 112 may be repeatedly operated in the idle mode and the normal driving mode according to the internal temperature of the refrigerator.

Here, the hot gas injection into the first heat exchange unit 106 through the second refrigerant circulation line 123 may be performed in the idle mode section of the compression unit 112 . That is, when the hot gas is injected into the first heat exchanger 106 in the normal driving mode section, the ice tray 102 is heated by the first heat exchanger 106, so that the ice maker 100 is installed. It takes more time to lower the internal temperature of the ice chamber to the preset first temperature T1. Accordingly, in the embodiment of the present invention, hot gas injection into the first heat exchanger 106 may be performed in the idle mode section of the compression unit 112 . In this case, the compression unit 112 may be normally driven for a predetermined time in the idle mode section. That is, in order to inject hot gas into the first heat exchanger 106 , the compression unit 112 may be normally driven for a predetermined time even in the idle mode section. Since the idle mode section is a section in which the temperature inside the refrigerator rises, even if the ice tray 102 is heated by injecting hot gas into the first heat exchanger 106 , the environment inside the refrigerator is not greatly affected.

The ice maker 100 may link the ice making cycle with the operation mode of the compression unit 112 . For example, the ice maker 100 may control the time point at which the ice making step is completed (or the start point of the ice removal step) becomes the idle mode section of the compression unit 112 . Then, the ice tray 102 can be heated by injecting hot gas into the first heat exchanger 106 in the ice-moving step after the completion of the ice-making step. The ice maker 100 may link the ice making cycle with the internal temperature of the refrigerator. For example, in the ice maker 100 , the time point at which the ice making step is completed (or the start point of the ice removal step) becomes a section in which the internal temperature of the refrigerator rises from the preset first temperature T1 to the preset second temperature T2. can be controlled Then, even when the ice tray 102 is heated by injecting hot gas into the first heat exchanger 106 at the completion of the ice making step or the start of the ice making step, the ice is poured into the ice tray ( 102) can be separated from the inner wall.

Although the present invention has been described in detail through representative embodiments above, those of ordinary skill in the art to which the present invention pertains can make various modifications to the above-described embodiments without departing from the scope of the present invention. will understand Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims described below as well as the claims and equivalents.

100: ice machine
102: ice tray
104: ejector
104-1: ejector shaft
104-2: ejector pin
106: first heat exchange unit
108: ice heater
110: water supply
112: compression unit
114: second heat exchange unit
116: expansion valve
121: first refrigerant circulation line
123: second refrigerant circulation line
125: first refrigerant switching valve
127: second refrigerant switching valve

Claims (21)

an ice tray having an ice making space accommodating the ice making water therein, the ice making space being partitioned through a plurality of partition walls, and fixed in the ice making chamber;
an ejector provided on the ice tray and rotating in a predetermined direction to eject the ice in the ice tray; and
a first heat exchanger provided in contact with an outer surface of the ice tray;
a compression unit for compressing and discharging the refrigerant heat-exchanged in the first heat exchange unit into a high-temperature and high-pressure gas;
a second heat exchanger configured to heat-exchange the high-temperature and high-pressure refrigerant discharged from the compression unit and condense it into a medium-temperature and high-pressure refrigerant; and
Including; an evaporator for evaporating the refrigerant condensed in the second heat exchange unit;
The first heat exchanger cools the ice tray in the ice-making step and heats the ice tray in the ice-making step;
and an expansion valve configured to expand the refrigerant compressed in the compression unit and send it to the first heat exchange unit.
The method according to claim 1,
The ice maker,
a first refrigerant circulation line including the compression unit, the second heat exchange unit, and the evaporator, constituting a cooling cycle of the refrigerant;
a second refrigerant circulation line branched from the compression unit and connected to the first heat exchange unit to heat the ice tray; and
The ice maker further comprising a first refrigerant switching valve provided at the branching point of the second refrigerant circulation line and controlling a flow direction of the refrigerant according to the ice making step and the ice breaking step.
3. The method according to claim 2,
The first refrigerant switching valve,
In the ice making step, the first refrigerant circulation line is opened and the second refrigerant circulation line is cut off, and in the ice moving step, the first refrigerant circulation line is cut off and the second refrigerant circulation line is opened.
3. The method according to claim 2,
The ice maker,
The ice maker further comprising a second refrigerant switching valve provided on the inlet side of the first heat exchanger and controlling a flow direction of the refrigerant according to the ice making step and the ice breaking step.
5. The method according to claim 4,
The second refrigerant switching valve,
In the ice making step, the first refrigerant circulation line is opened and the second refrigerant circulation line is cut off, and in the ice moving step, the first refrigerant circulation line is cut off and the second refrigerant circulation line is opened.
The method according to claim 1,
The ejector is
When a preset time elapses after the first heat exchanger heats the ice tray, or when the temperature of the ice tray becomes higher than or equal to a preset temperature, or when the first heat exchanger heats the ice tray for a preset time when the temperature of the ice tray is greater than or equal to a preset temperature, the ice maker rotates to remove the ice in the ice tray.
The method according to claim 1,
The ice maker is provided in the refrigerator,
The ice maker heats the ice tray by introducing a refrigerant discharged from a compression unit or a second heat exchange unit constituting a cooling cycle of the refrigerator into the first heat exchange unit.
8. The method of claim 7,
The ice maker,
and heating the ice tray by introducing the refrigerant into the first heat exchanger during a rest mode section of the compression unit.
The method according to claim 1,
The ice maker is provided in the refrigerator,
An ice maker that adjusts an ice making cycle according to an operation mode of a compression unit constituting a cooling cycle of the refrigerator.
10. The method of claim 9,
The ice maker,
and adjusting a completion time of the ice-making step or a start time of the ice-making step to an idle mode section of the compression unit.
The method according to claim 1,
The ice maker,
The ice maker further comprising an ice heater provided in contact with the outer surface of the ice tray.
12. The method of claim 11,
The ice heater is
The ice maker is driven when the ejector does not reach a preset position at a preset time after the ejector starts to rotate.
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